EP2141791A1 - Procédé et dispositif destinés au fonctionnement d'une machine asynchrone - Google Patents

Procédé et dispositif destinés au fonctionnement d'une machine asynchrone Download PDF

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Publication number
EP2141791A1
EP2141791A1 EP09100347A EP09100347A EP2141791A1 EP 2141791 A1 EP2141791 A1 EP 2141791A1 EP 09100347 A EP09100347 A EP 09100347A EP 09100347 A EP09100347 A EP 09100347A EP 2141791 A1 EP2141791 A1 EP 2141791A1
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EP
European Patent Office
Prior art keywords
modulation
degree
value
asynchronous machine
partial converter
Prior art date
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Granted
Application number
EP09100347A
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German (de)
English (en)
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EP2141791B1 (fr
Inventor
Martin GÖTZENBERGER
Stephan Bolz
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Continental Automotive GmbH
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Continental Automotive GmbH
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    • HELECTRICITY
    • H02GENERATION; CONVERSION OR DISTRIBUTION OF ELECTRIC POWER
    • H02PCONTROL OR REGULATION OF ELECTRIC MOTORS, ELECTRIC GENERATORS OR DYNAMO-ELECTRIC CONVERTERS; CONTROLLING TRANSFORMERS, REACTORS OR CHOKE COILS
    • H02P27/00Arrangements or methods for the control of AC motors characterised by the kind of supply voltage
    • H02P27/04Arrangements or methods for the control of AC motors characterised by the kind of supply voltage using variable-frequency supply voltage, e.g. inverter or converter supply voltage
    • H02P27/06Arrangements or methods for the control of AC motors characterised by the kind of supply voltage using variable-frequency supply voltage, e.g. inverter or converter supply voltage using dc to ac converters or inverters
    • H02P27/08Arrangements or methods for the control of AC motors characterised by the kind of supply voltage using variable-frequency supply voltage, e.g. inverter or converter supply voltage using dc to ac converters or inverters with pulse width modulation
    • HELECTRICITY
    • H02GENERATION; CONVERSION OR DISTRIBUTION OF ELECTRIC POWER
    • H02PCONTROL OR REGULATION OF ELECTRIC MOTORS, ELECTRIC GENERATORS OR DYNAMO-ELECTRIC CONVERTERS; CONTROLLING TRANSFORMERS, REACTORS OR CHOKE COILS
    • H02P23/00Arrangements or methods for the control of AC motors characterised by a control method other than vector control
    • H02P23/0004Control strategies in general, e.g. linear type, e.g. P, PI, PID, using robust control
    • HELECTRICITY
    • H02GENERATION; CONVERSION OR DISTRIBUTION OF ELECTRIC POWER
    • H02PCONTROL OR REGULATION OF ELECTRIC MOTORS, ELECTRIC GENERATORS OR DYNAMO-ELECTRIC CONVERTERS; CONTROLLING TRANSFORMERS, REACTORS OR CHOKE COILS
    • H02P27/00Arrangements or methods for the control of AC motors characterised by the kind of supply voltage
    • H02P27/04Arrangements or methods for the control of AC motors characterised by the kind of supply voltage using variable-frequency supply voltage, e.g. inverter or converter supply voltage
    • H02P27/06Arrangements or methods for the control of AC motors characterised by the kind of supply voltage using variable-frequency supply voltage, e.g. inverter or converter supply voltage using dc to ac converters or inverters

Definitions

  • the invention relates to a method and a device for operating an asynchronous machine.
  • the asynchronous machine has a rotor and at least two electrically separate stator windings.
  • the first and second stator windings are each assigned a plurality of winding phases.
  • the first stator winding is fed via a first partial converter and the second stator winding is fed via a second partial converter.
  • Asynchronous machines are used in the field of automotive technology, where they are used, for example, within a ventilator of a ventilation system for interior ventilation of a motor vehicle.
  • Asynchronous machines can be designed, for example, as a squirrel cage asynchronous machine. In such asynchronous machines, the rotor windings are electrically short-circuited.
  • Control devices which are designed to control the asynchronous machine, often comprise an inverter and can thus be charged on the input side with a direct current and a DC voltage. This is particularly advantageous when used in a motor vehicle, in which the vehicle electrical system provides a DC voltage and a DC current.
  • EP 0 840 441 B1 discloses a controller for an asynchronous machine.
  • the asynchronous machine is controlled by means of a field-oriented current control in their speed.
  • the d axis coincides with the orientation of the respective poles of the rotor, while the q axis is perpendicular to the d axis.
  • the d-axis is also referred to as the real axis and the q-axis as the imaginary axis.
  • DE 10 2005 043 576 A1 discloses an electric machine having at least two electrically separate stator windings.
  • the first stator winding is fed by means of a first partial converter and the second stator winding is fed by means of a second partial converter.
  • the object on which the invention is based is to provide a method and a device for operating an asynchronous machine, which ensures the lowest possible load on the DC link capacitor.
  • the invention is characterized by a method and a corresponding device for operating an asynchronous machine with a rotor and at least two electrically separated stator windings.
  • the first and second stator windings are each assigned a plurality of winding phases.
  • the first stator winding is fed via a first partial converter and the second stator winding is fed via a second partial converter.
  • the first and second partial converter are supplied from a common intermediate circuit, which has a link capacitor, with an intermediate circuit voltage.
  • a value of the DC link voltage is detected.
  • a first degree of modulation is determined.
  • a second degree of modulation is determined.
  • the first and second partial converter are controlled in such a way that the second modulation degree results from the control.
  • the second degree of modulation is determined in such a way that it is optimized during the activation of the asynchronous machine with regard to a low effective value of a DC link current provided by the DC link to the first and second partial converter, taking into account a secondary condition that an actual value the at least one operating variable is substantially equal to the desired value of the at least one operating variable.
  • the second degree of modulation is determined, for example, with the aid of a predefined table and / or a predetermined characteristic map in such a way that the control of such an asynchronous machine based on the second degree of modulation results in an effective value of the intermediate circuit current which is as low as possible, in particular minimal.
  • the data in the given table and / or in the given characteristic map take into account that the lowest possible effective value of the DC link current ensures a given operating state of the asynchronous machine.
  • the data of the given table and / or the predetermined characteristic field are determined, for example, by means of simulation.
  • the predetermined operating state is achieved when the actual value of the at least one operating variable, for example a torque and / or a rotational speed, is substantially the same its nominal value.
  • the second degree of modulation is determined as a function of a previously determined second degree of modulation.
  • the consideration of the previously determined second degree of modulation makes it possible in a particularly simple manner to determine the second degree of modulation, taking into account a hysteresis. If, for example, a possible first and second value of the second degree of modulation are assigned to a value of the first degree of modulation, an alternating specification of the first or second value of the second degree of modulation available can be avoided by determining the second degree of modulation as a function of the previously determined second degree of modulation becomes.
  • the value of the second degree of modulation that is available for selection is preferably selected, which has a smaller difference than the value of the previously determined second degree of modulation. If a second degree of modulation is determined, this is taken into account during a subsequent determination of a new second degree of modulation as a previously determined second degree of modulation.
  • a nominal value of a magnetic flux is determined, which is given to the asynchronous machine.
  • the determined magnetic flux determines a rotating field-forming motor current.
  • the rotating field-forming motor current preferably also has an influence on the determination of a torque-generating motor current in order to ensure the predetermined operating state of the asynchronous machine. This ensures a particularly reliable operation of the asynchronous machine and at the same time a low load on the DC link capacitor.
  • the invention is further characterized by a method and a corresponding device for operating an asynchronous machine with a rotor and at least two electrically separate stator windings.
  • the first and second stator windings are each assigned a plurality of winding phases.
  • the first stator winding is fed via a first partial converter and the second stator winding is fed via a second partial converter.
  • the first and second partial converter are supplied from a common intermediate circuit, which has a link capacitor, with an intermediate circuit voltage.
  • a degree of modulation is determined.
  • the first and second partial converter are controlled in such a way that the determined modulation degree results from the activation of the first and second partial converter.
  • the degree of modulation is determined in such a way that it is optimized during the activation of the asynchronous machine with regard to a low rms value of a DC link current provided by the DC link to the first and second partial converter, taking into account a secondary condition that an actual value of at least one operating variable is substantially equal to the desired value of the at least one operating variable.
  • This allows a particularly simple operation of the asynchronous machine, while the DC link capacitor at a such activation as low as possible, especially minimal, is charged.
  • the degree of modulation can be determined very quickly.
  • Such control of the asynchronous machine is particularly suitable for controlling the asynchronous machine, in which the at least one operating variable, such as the torque and / or the rotational speed, is specified.
  • FIG. 1 is schematically illustrated an asynchronous AM.
  • the asynchronous machine AM includes a rotor and first and second stator windings W1 and W2.
  • the first and second stator windings W1 and W2 are electrically isolated from each other.
  • the first stator winding W1 implements a first partial motor and the second stator winding W2 implements a second partial motor of the asynchronous machine AM.
  • the asynchronous machine AM can also have more than two stator windings.
  • the first and second stator windings W1 and W2 preferably each have three winding strands, which are each arranged as a result offset by 120 °.
  • the first stator winding W1 are associated with the first electrical winding terminals R1, S1, T2 and the second stator winding W2 are associated with the second electrical winding terminals R2, S2, T2.
  • An operating device OPU1 ( FIG. 2 ) is assigned to the asynchronous AM.
  • the operating device OPU1 comprises a regulator arrangement which is designed to realize a field-oriented current regulation.
  • the currents and voltages of the asynchronous machine AM are transformed into a coordinate system circulating with the rotor, a d, q coordinate system. This transformation is called Clarke Park Transformation.
  • Controlled variables can be, for example, a torque M of the asynchronous machine AM.
  • the operating device OPU1 may be referred to as a device for operating the asynchronous machine AM.
  • the operating device OPU1 comprises a calculation unit CALC, which is designed as a function of the setpoint value of the torque M and an actual flow ⁇ is a desired value iq setpoint of a torque-forming current component iq of the d, q coordinate system to investigate.
  • the torque-forming current iq can also be referred to as q-motor current.
  • the operating device to a block MOD which is formed, the actual flow ⁇ is observed on the output side is available.
  • the block MOD under the aid of a magnetic flux model of the induction machine AM depending on an actual speed n is the rotor of the induction machine AM and a temperature T MOTOR , which is detected for example by means of a temperature sensor in the stator of the asynchronous AM, the actual flow ⁇ is determined.
  • the position sensor S may for example be designed as a resolver. However, it may also be, for example, an incremental position sensor comprising a Hall element or the like.
  • a connection point VK2 is provided in the operating device OPU1, in which a difference between the desired value iq soll and an actual value iq ist of the q-motor current is formed, this difference then being supplied as a control difference to a block B9 which comprises a q-controller.
  • the q-controller can be designed for example as a PI controller.
  • the q-controller On the output side, the q-controller generates a value Uq of a q-voltage, which is fed as a control signal to a block B11.
  • an intermediate circuit voltage U ZK of a DC link ZK is predetermined on the input side of the operating device OPU1.
  • the DC link ZK is, for example, with an electrical vehicle electrical system of a motor vehicle electrically coupled and has an intermediate circuit capacitor C ZK , which is arranged electrically parallel to a vehicle electrical system voltage supply, which is formed for example as a battery of the motor vehicle and the DC link ZK provides a supply voltage U BAT .
  • About the DC link capacitor C ZK drops the intermediate circuit voltage U ZK .
  • the asynchronous machine AM is controlled by means of a first and second partial converter, which in FIG. 2 are integrated in an actuator B15.
  • the first partial converter of the actuator B15 is electrically coupled to the first winding terminals R1, S1, T1 of the first stator winding W1.
  • the second partial converter of the actuator B15 is electrically coupled to the second winding terminals R2, S2, T2 of the second stator winding W2.
  • the first and second partial converters are designed, for example, as three-phase inverters and supply the asynchronous machine AM with the desired conductor voltages.
  • the actuator B15 is assigned to the input side of the intermediate circuit ZK.
  • the intermediate circuit ZK acts on the first and second partial converter of the actuator B15 with the intermediate circuit voltage U ZK .
  • the operating device OPU1 further comprises a first and a second detection unit B1 and B3, whose input side, the intermediate circuit voltage U ZK , the desired value of the torque M and the actual speed n is assigned to the rotor of the asynchronous machine AM.
  • the first determination unit B1 is designed to determine a first modulation degree m 1 as a function of the input variables. The determination of the first degree of modulation m 1 is preferably carried out such that when operating the asynchronous machine AM with the predetermined torque M, the efficiency is as large as possible, in particular maximum, is.
  • the first determination unit B1 is also designed to determine a second modulation degree m 2 as a function of the first modulation degree m 1 .
  • the value of the first degree of modulation m 1 preferably differs from the value of the second degree of modulation m 2 , wherein it is fundamentally also possible for the determined value of the second degree of modulation m 2 to be equal to the value of the first degree of modulation m 1 .
  • the first determination unit B1 can also have a memory in which a previously determined second modulation degree m 2_prev is stored. In this case, the first determination unit B1 can be designed to determine a new second modulation degree m 2 as a function of the second modulation level m 2_prev stored in the memory. As a result, a hysteresis with respect to the determination of the second degree of modulation m 2 is taken into account.
  • a possible first and second value of the second modulation degree m 2 is assigned to the determined value of the first modulation degree m 1 .
  • An alternating specification of the first or second value of the second degree of modulation m 2 that is available for selection can be avoided by determining the second degree of modulation m 2 as a function of the previously determined second modulation degree m 2_prev .
  • the value of the second modulation degree m 2 that is available for selection is preferably selected, which has a smaller difference than the value of the previously determined second modulation degree m 2_prev . If a second degree of modulation m 2 is determined, this is taken into account during the subsequent determination of a new second modulation degree m 2 as a previously determined second modulation degree m 2_prev .
  • the second degree of modulation m 2 is supplied on the input side as a further input variable of the second detection unit B3.
  • the second determination unit B3 is designed to be dependent from the input variables supplied to it, a setpoint flux ⁇ should be provided on the output side.
  • the first and second determination units B1 and B3 preferably each comprise a data memory.
  • a respective predefined assignment of the respective input variables to the first modulation level m 1 and an assignment of the determined first modulation level m 1 to the second modulation degree m 2 in the data memory of the first determination unit B1 are stored in tabular form and / or in the form of a characteristic field.
  • a predefined assignment of the respective input variables to the desired flow ⁇ soll is stored in tabular form and / or in the form of a characteristic field.
  • the data stored in the data memory of the first and / or second determination unit B1 and / or B3 can be determined, for example, by means of a simulation. Furthermore, it is conceivable to determine the data in a test setup with the asynchronous machine AM. In principle, other types of determination of the respective output variables are conceivable.
  • a connection point VK2 is provided in the operating device OPU1, in which a difference between the setpoint flux ⁇ soll and the actual flow ⁇ ist is formed, this difference being supplied as a control difference to a block B5, which preferably comprises a PI controller.
  • a block B5 which preferably comprises a PI controller.
  • On the output side of the PI controller generates an actual value id is a rotating field-producing current component id of the d, q-coordinate system.
  • the rotating field-forming current id can also be referred to as d-motor current.
  • Another node VK3 is provided in the operating device OPU1 in which a difference between the Setpoint id soll and an actual value id is the d-motor current is formed, this difference is then fed as a control difference a block B7, which includes a d-controller.
  • the d-controller can be designed for example as a PI controller.
  • the d-controller On the output side, the d-controller generates a value U d of a d-voltage, which is supplied as a control signal to the block B11.
  • the operation device OPU1 further comprises a block B13, the actual value iq is the q-motor current id and the actual value of the d-motor current on the output side provides.
  • Block B13 is designed as a first transformation block for carrying out a parking and Clarke transformation and thus carrying out a corresponding transformation of detected phase currents i R , i S , i T into the corresponding q and d motor currents of the d, q coordinate system.
  • the d, q coordinate system is characterized by the fact that the corresponding transformed motor currents and voltages are time-invariant with a knowledge of exact rotational angles ⁇ in a stationary operation of the asynchronous machine AM.
  • the operating device OPU1 further comprises the block B11 to which the value Uq of the q-voltage as the first actuating signal and the value U d of the d-voltage as the second actuating signal are supplied on the input side.
  • the block B11 is designed as a second transformation block to carry out an inverse Park and Clarke transformation and thus to perform a corresponding transformation of the q and d voltage of the q, d coordinate system into corresponding r, s, t coordinates and thus to specification corresponding intermediate voltages U R , U S , U T is used.
  • the intermediate voltages U R , U S , U T are fed to the input side of a modulation unit, which is integrated in the actuator B15.
  • the modulation unit is preferably designed to carry out a sine-wave modulation. In principle, other modulations can be used, such as a Space vector modulation.
  • the first and second partial converter of the actuator B15 are activated.
  • FIG. 3 is a section of the sine-wave modulation, as it is performed by the modulation unit of the actuator B15 shown.
  • sine-wave modulation is associated with the first stator winding W1.
  • a first triangular voltage U TRI_1 the characteristics of the three sinusoidal intermediate voltages U R , U S , U T phase-shifted by 120 ° are shown. If the respective progression of the intermediate voltage U R , U S , U T intersects the profile of the first triangular voltage U TRI_1, the first partial converter is correspondingly driven, on the output side, first phase voltages U SR1 , U SS1 , U ST1 corresponding to FIG.
  • a sine-triangle modulation for the second stator winding W2 is analogous, with the difference that a curve of a second triangular voltage is out of phase with the curve of the first triangular voltage U TRI_1 .
  • a degree of modulation such as the second degree of modulation m 2 , preferably represents a ratio of an amplitude U AMP of the intermediate voltages U R , U S , U T to the value of the intermediate circuit voltage U ZK .
  • the intermediate circuit voltage U ZK can be regarded as approximately constant.
  • An enlargement of the second degree of modulation m 2 is preferably associated with an increase in the amplitude U AMP of the intermediate voltages U R , U S , U T.
  • the increase of the amplitude U AMP of the intermediate voltages U R , U S , U T are in turn assigned to changed pulse widths of the first and second phase voltages U SR1 , U SS1 , U ST1 .
  • a reduction of the second modulation degree m 2 is preferably associated with a reduction of the pulse widths of the first and second currents I MOT1 and I MOT2 .
  • FIG. 4a a course of the first and second current I MOT1 and I MOT2 is shown.
  • the first and second currents I MOT1 and I MOT2 are made available to the actuator B15 by the DC link ZK as a DC link current I MOT resulting from the first and second currents I MOT1 and I MOT2 .
  • a battery current I BAT represents an average value of a current that is provided by the supply voltage U BAT for operating the asynchronous machine AM to the first and second partial converter.
  • a current difference between the course of the battery current I BAT and a maximum of the first or second current I MOT1 and I MOT2 is provided by the intermediate circuit capacitor C ZK as a capacitor current I CZK .
  • the greater the current difference the greater the load on the intermediate circuit capacitor C ZK , with a high load of the intermediate circuit capacitor C ZK, for example makes noticeable by a strong heating and a resulting reduced possible operating time of the intermediate circuit capacitor C ZK .
  • the pulse widths of the current pulses of the first and second currents I MOT1 and I MOT2 can be changed.
  • the second degree of modulation m 2 is predetermined such that an effective value I EFF1 of the DC link current I MOT is as low as possible, in particular minimal.
  • the variation of the second degree of modulation results in m 2 current pulses of the first and second currents I MOT1 and I MOT2 , which are lined up in time or overlap in time.
  • the resulting DC link current I MOT is designed such that a predetermined operating state of the asynchronous machine AM, such as a provision of the predetermined torque M, is guaranteed.
  • the predetermined operating state preferably results from a substantially identical actual and desired value of the operating variable, for example the torque M.
  • FIG. 4b For comparison, a temporal representation of a DC link current I MOT is shown, which is assigned to an operation of an asynchronous machine with only one stator winding.
  • the individual current pulses each have higher current values and greater time intervals relative to one another.
  • An effective value I EFF2 of the intermediate circuit current I MOT resulting from this current profile would have a higher value in comparison to the effective value I EFF1 , which consists of the in FIG. 4a shown course of the DC link current IMOT results.
  • the current difference between the battery current I BAT and the maximum of the DC link current I MOT in FIG. 4b is compared to the current difference in several stator winding according to the FIG. 4a relatively large and thus also a load on the DC link capacitor C ZK .
  • the respective determined values of the second degree of modulation m 2 preferably differ from the respective determined values of the first modulation degree m 1 . This has the consequence that from the second degree of modulation m 2 resulting setpoint value id to the d-motor current at a setting of the target value of the torque M is id to from the target value of d-motor current that would result from the first degree of modulation m is 1, differs, which would also result from the specification of the first modulation degree m 1, the predetermined torque M at the rotor.
  • the asynchronous machine M is designed to provide, for example, the predetermined torque M on the rotor even with different predetermined activations of the asynchronous machine AM.
  • FIG. 5a two torque-speed characteristics of the induction machine AM are shown.
  • a first control of the asynchronous machine AM is a first characteristic 1
  • a second control of the asynchronous machine AM is assigned a second characteristic 2.
  • Both curves 1 and 2 intersect at an intersection IS, which is assigned a common speed n IS and a common torque M IS .
  • the first modulation level m 1 could be assigned to the second characteristic curve 2
  • the second modulation level m 2 could be assigned to the first characteristic curve 1.
  • FIG. 5b is shown a relationship of the d-motor current id to the q-motor current iq for the common torque M IS .
  • a first d-motor current id1 and a corresponding first q-motor current iq1 the common torque M IS .
  • a second d-motor current id2 and a corresponding second q-motor current iq2 associated with the common torque M IS .
  • a third d-motor current id3 and a corresponding third q-motor current iq3 results in the common torque M IS .
  • a desired value id soll of the d-motor current is predetermined.
  • a corresponding setpoint value iq soll of the q-motor current is assigned to this predetermined desired value id soll of the d-motor current in order to be able to provide the predetermined torque M.
  • the target value iq to the q-motor current is dependent on the actual flow ⁇ , which is specified by the calculation unit CALC, id to the target value of d-motor current should adjusted so that the predetermined torque M is provided on the rotor of the asynchronous machine AM.
  • the second modulation degree m 2 is determined such that the effective value of the intermediate circuit current I MOT is as low as possible, in particular minimal, taking into account the secondary condition that the actual value of the torque M is substantially equal to its nominal value.
  • a sequence is processed in the first and second determination units B1 and B3, which in the following is based on the flowchart of FIG. 6 is explained in more detail.
  • the sequence may be provided as hard-wired logic but also in the form of a program that is stored in a memory of the operating device OPU1 and is processed in a computing unit during operation.
  • a start takes place.
  • a step S3 depending on the desired value of the torque M and the intermediate circuit voltage U ZK , for example by means of a voltage sensor is detected, and the actual speed n is the first modulation degree m 1 determined.
  • the first modulation degree m 1 is typically associated with an efficiency of the asynchronous machine AM during operation of the asynchronous machine AM with the predetermined torque M, which is as large as possible, in particular maximum.
  • the second modulation degree m 2 is determined in a step S5.
  • the second degree of modulation m 2 is determined on the basis of the data memory in the first determination unit B1, wherein the data in the data memory take into account that during operation of the asynchronous machine AM with the predetermined torque M the effective value I EFF1 of the intermediate circuit current I MOT is as low as possible, in particular minimal, is.
  • This has the advantage that the capacitor current I ZK , the DC link capacitor C ZK contributing to the DC link current I MOT , as low as possible, especially minimal, and the DC link capacitor C ZK is thus minimized.
  • the desired flux ⁇ soll is determined and made available.
  • the process is ended. Alternatively, however, the process can also be restarted in step S3.
  • FIG. 7 is another operating device OPU2 for operating the asynchronous machine AM, which is analogous to the FIG. 1 is formed, shown.
  • the further operating device OPU2 comprises a block B17, which may be referred to as a third determining unit.
  • the asynchronous machine AM is designed as a motor for a ventilator for ventilation of an interior of the motor vehicle.
  • a speed n is specified.
  • the specification of the speed n of the asynchronous machine AM is preferably carried out stepwise.
  • three stages of different rotational speed n of the further operating device OPU2 are specified, for example a low, a medium and a high rotational speed n.
  • the further operating device OPU2 has a further actuator ACT, which is analogous to the actuator B15 in FIG. 2 is formed, with the difference that the input side, the value of a degree of modulation m is supplied. Furthermore, the further actuator ACT is electrically coupled analogously to the actuator B15 with the first and second stator winding W1 and W2 of the asynchronous machine AM. The first and second partial converter of the further actuator ACT are analogous to the FIG. 2 The input side of the intermediate circuit voltage U ZK of the intermediate circuit ZK acted upon.
  • the third determination unit B17 is designed to determine the modulation degree m as a function of the predetermined rotational speed n and make it available to the further actuator ACT.
  • the determination of the degree of modulation m is such that the effective value of the intermediate circuit current I MOT is as low as possible, in particular minimal, with the constraint that the actual value of the rotational speed n is substantially equal to the predetermined value of the rotational speed n.
  • FIG. 7 a control of the speed of the asynchronous machine AM is shown, and thus the actual speed of the rotor can fundamentally deviate from the specification of the speed n.
  • this deviation between the actual value of the rotational speed n and the specification of the rotational speed n can be designated as essentially the same with regard to the control of the rotational speed n.
  • the determination of the degree of modulation m can be carried out in the third determination unit B17, for example by an assignment of the modulation degree m to the predetermined speed n by means of a predetermined table and / or by means of a predetermined map, which are stored for example in a data memory of the third detection unit B17.
  • the data are determined, for example, by means of a simulation or by means of a test setup with the asynchronous machine AM and stored in the data memory.
  • the further actuator ACT is designed to control the asynchronous machine AM depending on the predetermined modulation degree m such that the predetermined rotational speed n is at least approximately provided by the asynchronous machine AM and at the same time an effective value of the DC link current I MOT is as low as possible, in particular minimal.

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  • Engineering & Computer Science (AREA)
  • Power Engineering (AREA)
  • Control Of Ac Motors In General (AREA)
EP09100347A 2008-07-02 2009-06-26 Procédé et dispositif destinés au fonctionnement d'une machine asynchrone Active EP2141791B1 (fr)

Applications Claiming Priority (1)

Application Number Priority Date Filing Date Title
DE102008031268A DE102008031268A1 (de) 2008-07-02 2008-07-02 Verfahren und Vorrichtung zum Betreiben einer Asynchronmaschine

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EP2141791A1 true EP2141791A1 (fr) 2010-01-06
EP2141791B1 EP2141791B1 (fr) 2012-07-18

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DE102012107065A1 (de) * 2012-08-02 2014-02-06 Ssb Wind Systems Gmbh & Co. Kg Steuerungsvorrichtung für einen Rotorblattverstellantrieb einer Windkraftanlage
DE102013200672A1 (de) * 2012-12-19 2014-06-26 Bayerische Motoren Werke Aktiengesellschaft Vorrichtung und Verfahren zum Ansteuern einer Elektromaschine

Citations (5)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
EP0840441B1 (fr) 1996-11-04 1999-05-12 Siemens Aktiengesellschaft Régulation à orientation de champ en limite de tension pour une machine à champ tournant
EP1521356A2 (fr) 2003-09-30 2005-04-06 Vacon Oyj Contrôle des convertisseurs ou invertisseurs de fréquence opérés en parallèle
US20050225270A1 (en) 2004-04-12 2005-10-13 York International Corporation System and method for controlling a variable speed drive
DE102005043576A1 (de) 2005-09-12 2007-03-15 Conti Temic Microelectronic Gmbh Verfahren zum Betrieb einer elektrischen Maschine
EP1914108A1 (fr) 2005-08-08 2008-04-23 Toyota Jidosha Kabushiki Kaisha Dispositif d alimentation en courant de vehicule

Patent Citations (5)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
EP0840441B1 (fr) 1996-11-04 1999-05-12 Siemens Aktiengesellschaft Régulation à orientation de champ en limite de tension pour une machine à champ tournant
EP1521356A2 (fr) 2003-09-30 2005-04-06 Vacon Oyj Contrôle des convertisseurs ou invertisseurs de fréquence opérés en parallèle
US20050225270A1 (en) 2004-04-12 2005-10-13 York International Corporation System and method for controlling a variable speed drive
EP1914108A1 (fr) 2005-08-08 2008-04-23 Toyota Jidosha Kabushiki Kaisha Dispositif d alimentation en courant de vehicule
DE102005043576A1 (de) 2005-09-12 2007-03-15 Conti Temic Microelectronic Gmbh Verfahren zum Betrieb einer elektrischen Maschine

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